A multi bits flash memory device and a method of operating the same are disclosed. The multi bits flash memory device includes: a stacked structure including: a first active layer with a mesa-like form disposed on a substrate; a second active layer, having a different conductivity type from the first active layer, formed on the first active layer; an active interlayer isolation layer interposed between the first active layer and the second active layer such that the first active layer is electrically isolated from the second active layer; a common source and a common drain formed on a pair of opposite side surfaces of the stacked structure; a common first gate and a common second gate formed on the other pair of opposite side surfaces of the stacked structure; a tunnel dielectric layer interposed between the first and second gates and the first and second active layers; and a charge trap layer, storing charges that tunnel through the tunnel dielectric layer, interposed between the tunnel dielectric layer and the first and second gates.
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13. A flash memory device comprising:
two nMOS transistors having a common source and a common drain, and each having an independent gate and a charge trap layer formed below the independent gate;
two pMOS transistors, having a common source and a common drain, and each having an independent gate and a charge trap layer formed on the nMOS transistors; and
an isolation layer interposed between the nMOS transistors and the pMOS transistors such that an n-channel is electrically isolated from a p-channel.
1. A flash memory device comprising:
a stacked structure comprising:
a first active layer with a mesa-like form disposed on a substrate;
a second active layer, having a different conductivity type from the first active layer, formed on the first active layer;
an active interlayer isolation layer interposed between the first active layer and the second active layer such that the first active layer is electrically isolated from the second active layer;
a common source and a common drain formed on a pair of opposite side surfaces of the stacked structure;
a common first gate and a common second gate formed on the other pair of opposite side surfaces of the stacked structure;
a tunnel dielectric layer interposed between the first and second gates and the first and second active layers; and
a charge trap layer, storing charges that tunnel through the tunnel dielectric layer, interposed between the tunnel dielectric layer and the first and second gates.
9. flash memory device comprising:
a stacked structure having a hexahedral mesa-like form and comprising:
a first active layer formed on a substrate; and
a second active layer formed on the first active layer and having a different conductivity type from the first active layer;
an active interlayer isolation layer, which is interposed between the first active layer and the second active layer such that the first active layer is electrically isolated from the second active layer;
an assistant control electrode connected to the second active layer and through which a body voltage is applied to the second active layer;
a common source and a common drain formed on a pair of opposite side surfaces of the stacked structure;
a common first gate and a common second gate formed on the other pair of opposite side surfaces of the stacked structure;
a tunnel dielectric layer interposed between the first and second gates and the first and second active layers; and
a charge trap layer, storing charges that tunnel through the tunnel dielectric layer, interposed between the tunnel dielectric layer and the first and second gates.
17. A method of operating a flash memory device, the method comprising storing various states in a memory cell by applying predetermined combinations of voltages to a first gate, a second gate, an assistant control electrode, and a first active layer of the memory cell, wherein the memory cell comprises:
a stacked structure having a hexahedral mesa-like form and comprising:
the first active layer formed on a substrate; and
a second active layer formed on the first active layer and having a different conductivity type from the first active layer;
an active interlayer isolation layer, which is interposed between the first active layer and the second active layer such that the first active layer is electrically isolated from the second active layer;
the assistant control electrode connected to the second active layer and through which a body voltage is applied to the second active layer;
a common source and a common drain formed on a pair of opposite side surfaces of the stacked structure;
the common first gate and the common second gate formed on the other pair of opposite side surfaces of the stacked structure;
a tunnel dielectric layer interposed between the first and second gates and the first and second active layers; and
a charge trap layer, storing charges that tunnel through the tunnel dielectric layer, interposed between the tunnel dielectric layer and the first and second gates.
2. The flash memory device of
3. The flash memory device of
4. The flash memory device of
5. The flash memory device of
6. The flash memory device of
7. The flash memory device of
10. The flash memory device of
11. The flash memory device of
12. The flash memory device of
14. The flash memory device of
15. The flash memory device of
16. The flash memory device of
18. The method of
−15 V to 15 V is applied to the first gate;
−15 V to 15 V is applied to the second gate;
−10 V to 10 V is applied to the assistant control electrode; and
0 V is applied to the first active layer or the first active layer or grounded.
19. The method of
20. The method of
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This application claims the benefit of Korean Patent Application No. 10-2004-0090892, filed on Nov. 9, 2004, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein in its entirety by reference.
1. Field of the Invention
The present invention relates to a semiconductor device, and more particularly, to a multi bits flash memory device using a complementary metal oxide semiconductor (CMOS) and a method of operating the same.
2. Description of the Related Art
In order to increase memory density, the sizes of memory cells can be reduced. Alternatively, memory density can be increased by increasing the number of possible states of charges in each memory cell. For example, it is reported a flash memory cell having multi floating gates that can assume 4 states and, therefore, store 2 bits simultaneously.
However, memory cells have often been embodied in two dimension-structures. Two-dimensional memory cells have, in general, a planar transistor structure in which source and drain regions are formed in a substrate, a channel is formed in a portion of the substrate between the source/drain region, and a gate is formed on the channel.
Such two-dimensional devices may be operated by two bits. For example, in a 2-dimentional planar transistor including a floating gate or a charge trap layer, both ends of the floating gate or the charge trap layer adjacent to source and drain regions are used as charge storage sites or storage nodes, thus implementing 2 bit operations. However, 2-dimentional devices are not suitable for multi-bit operation more than 3 bits in performing program, erase and read operations.
In addition, multi-level memory cells with 2-dimentional structures have been developed. Floating gates of such multi-level memory cells store charges in multi levels. In this case, in order to store more than 2 bits, for example, 4 bits, at least 24, that is, 16 charge levels are required. In a nMOSFET device, a threshold voltage Vth is expected to be about 3V at a doping concentration of about 1E+18/cm3, which can be increased as the number of the donor (Nd) increases and varies according to a doping concentration of a channel or a substrate. Therefore, a threshold voltage window (ΔVth) is expected to be 3V. Such a narrow threshold voltage window hinders the obtainment of various voltage levels of more than ten in the window range, and good program/erase and read operations.
Therefore, in order to implement more than 2 bits-operation in a memory cell, for example, 4 bits or 8 bits-operation, a new memory cell with at least two charge storage sites or storage nodes must be developed.
The present invention provides a multi bits flash memory device with a memory cell structure capable of storing more than 2 bits.
The present invention also provides a flash memory device including: a stacked structure including: a first active layer with a mesa-like form disposed on a substrate; a second active layer, having a different conductivity type from the first active layer, formed on the first active layer; an active interlayer isolation layer interposed between the first active layer and the second active layer such that the first active layer is electrically isolated from the second active layer; a common source and a common drain formed on a pair of opposite side surfaces of the stacked structure; a common first gate and a common second gate formed on the other pair of opposite side surfaces of the stacked structure; a tunnel dielectric layer interposed between the first and second gates and the first and second active layers; and a charge trap layer, storing charges that tunnel through the tunnel dielectric layer, interposed between the tunnel dielectric layer and the first and second gates.
When programming the flash memory device, a plurality of different states can be stored in the memory cell by combination of voltages applied to the first gate, the second gate, the assistant control electrode, and the first active layer.
For example, −15V to 15V can be applied to the first gate; −15V to 15V can be applied to the second gate; −10V to 10V can be applied to an assistant control electrode; and 0V can be applied to the first active layer or the first active layer can be grounded.
At this time, the source and the drain may be grounded or floated such that charges tunnel into the charge trap layer by a FN tunneling mechanism.
In addition, an electric field may be applied between the source and the drain to generate hot electrons such that charges are injected into the charge trap layer by a CHEI mechanism.
The present invention discloses a multi bits flash memory device with a memory cell structure capable of performing more than 2 bits.
The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which:
The present invention will now be described more fully with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown. The invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the invention to those skilled in the art.
A 3-dimentional multi bits flash memory device according to embodiment of the present invention includes two active layers and an active interlayer isolation layer interposed therebetween. The active layers and the active interlayer isolation layer form a stacked structure in the form of a hexahedron. A source, a drain, and gates formed on side surfaces of the stacked structure. A channel is formed in each of the active layers, and the active interlayer isolation layer is used as an insulator. A common source and a common drain are formed on a pair of opposite side surfaces of the stacked structure, and common gates are formed on the other pair of opposite side surfaces of the stacked structure. A charge trap layer is interposed between the common gates and side surfaces of the active layers. Further, an assistant control electrode is formed on an upper active layer such that a body voltage can be applied to the upper active layer. In addition, the lower active layer is electrically connected to a substrate such that a body voltage can be applied to the lower active layer through the substrate.
In a cell including such a 3-dimentional memory device, the active layers have different conductivity types so that at least two charge storage nodes below a single gate, which store charges can be formed on either side of the stack of the active layers. Accordingly, a memory cell may have a total of 4 charge storage sites or 8 charge storage sites. Since the active layers have p-type conductivity and n-type conductivity, respectively, each of the gates formed on side surfaces of the active layers is a common gate of an nMOS-type transistor and pMOS-type transistor. Accordingly, at least two charge storage sites can be formed below the gate. In other words, charges can be independently stored in respective isolated charge storage nodes such that at least 4 bits programming/erasing and reading can be realized.
Referring to
Referring to
A stacked structure of the first active layer 110, the active interlayer isolation layer 210, and the second active layer 130 can be realized by forming a silicon on insulating (SOI) substrate. That is, an SOI substrate is formed and then conductivity types of the first active layer 110 and the second active layer 130 are converted, thus obtaining the stacked structure shown in
The stacked structure is patterned to form a hexahedron on sides of which the common source, the common drain, and the common gate are formed.
Referring to
The substrate 100 may be a p-type silicon substrate doped with a doping concentration or the number (Na) of an acceptor of about 10E18/cm3. Accordingly, the first active layer 110 may be a p-type silicon layer, the same conductivity type as the substrate 100. The second active layer 130, which is an n-type silicon layer doped with a doping concentration or the number (Nd) of donor of about 10E18/cm3, may be formed on the active interlayer isolation layer 210. The active interlayer isolation layer 210 may be composed of BOX including an insulating material, such as silicon oxide. In this case, an n-channel of the nMOS transistor can be formed in the first active layer 110, and a p-channel of the pMOS transistor can be formed in the second active layer 130.
Referring to
A first gate 410 and a second gate 430 are formed on the other pair of opposite side surfaces of the stacked structure. The first and second gates 410 and 430 may be composed of a conducting material, and cover side surfaces of both the two active layers 110 and 130. Accordingly, each of the first and second gates 410 and 430 is used as a common gate overlapping channels which are formed in the first and second active layers 110 and 130.
As a result, the first and second gates 410 and 430 can control two channels respectively formed in the first and second active layers 110 and 130 at the same time. That is, when a voltage is applied to the first gate 410 or the second gate 430, the voltage can flow through the n-channel in the first active layer 110, or through the p-channel in the second active layer 130.
A tunnel dielectric layer 230 composed of a dielectric material, such as a silicon oxide, is formed between the first and second gates 410 and 430 and side walls of the first and second active layers 110 and 130. The tunnel dielectric layer 230 allows charges to tunnel through channels formed in the first and second active layers 410 and 430.
Referring to
Referring to
When charges are trapped in respective storage nodes, which are differentiated when the memory device according to the present embodiment is programmed, a body voltage may be applied to a body of the first active layer 410 or the second active layer 430. Applying a first body voltage to the substrate 100 may be substantially equivalent to applying the first body voltage to the first active layer 110 since the first active layer 110 is electrically connected to the substrate 100. A second body voltage is applied to the second active layer 130, independently from the first active layer 110. Thus, an assistant control electrode 450 electrically connected to the second active layer 130 is formed on an upper surface of the second active layer 130 such that the second body voltage need not be directly applied to the second active layer 130. The assistant control electrode 450 may be composed of a conducting material.
Since the first and second gates 410 and 430 are vertically formed on side surfaces of the active layer stack, a first insulator 610 can be formed between the first and second gates 410 and 430 and a surface of the substrate 100 below the first active layer 110. The first insulator 610 may be composed of a silicon oxide. In addition, a second insulator 630, composed of silicon oxide, may electrically isolate the assistant control electrode 450 from the first and second gates 410 and 430.
As mentioned above, the unit cell of the memory device according to the present embodiment includes a pMOS transistor and an nMOS transistor, which are complementarily combined. Therefore, the unit cell can be programmed by sequentially scanning and applying discontinuous voltages within a predetermined range, for example, about −5V to +5V to the first gate 410 or the second gate 430, applying a voltage VD of about 1V to a drain 530; and grounding a source 510 (Vs=0). The pMOS transistor and the nMOS transistor need different voltage conditions for formation of a channel and a current flow, thus being independently operated by the common gate 410 or the common gate 430, the common source 510, and the common drain 550.
Referring to
Therefore, referring to
That is, the pMOS transistor and the nMOS transistor have different threshold voltages Vth. The difference in threshold voltages is used to independently perform program and/or read operations with the nMOS transistor or the pMOS transistor formed below the common gate 410 or 430. The threshold voltage Vth may vary according to a concentration of a dopant in the substrate, that is, a doping concentration of the fist active layer 110 and a concentration of a dopant in the second active layer 130.
Referring to
Referring to
Referring to
Referring to
Referring to
Referring to
Referring to
Referring to
Referring to
As mentioned above, the strength and direction of an electric field applied to the four storage nodes 700 varies according to a bias applied to the device. Charges are trapped in the four storage nodes 700 in response to the electric field. That is, 16 states of an electric field can be realized by an FN tunneling mechanism such that 4 bits can be stored in the memory device according to the present embodiment. In other words, the programming operation can be independently performed at each of the charge storage nodes 700. Such independent operations make it possible for the programming operation to be performed at high speed.
Referring to
The stored data can be erased using the FN tunneling mechanism at once. Or, the electric field at the charge storage nodes 700 may be changed by independently changing the voltages applied to the each of charge storage nodes 700 of the memory device. That is, the data stored in each of the storage nodes can be independently erased at a high speed.
In addition, the reading operation may be performed by scanning the first gate 410 with a voltage in the range of −5V to 5V, scanning the second gate 430 with a voltage in the range of −5V to 5V, applying 1V to the drain 550, and applying 0V to the source 510 or floating the source 510. At this time, the first gate 410 and the scanning of the second gate 430 are independently scanned. In this case, by combining voltages independently applied to the first gate 410 and the second gate 430 and detected currents, data which are stored in the charge storage nodes 700, may be read. Independent reading by each of the first gate 410 and the second gate 430 results in an increase in a reading rate.
As mentioned above, a multi bits flash memory device according to an embodiment of the present invention includes: a stacked structure having a hexahedral mesa-like form and comprising a first active layer formed on a substrate, and a second active layer formed on the first active layer and having a different conductivity type from the first active layer; an active interlayer isolation layer interposed between the first active layer and the second active layer such that the first active layer is electrically isolated from the second active layer; a common source and a common drain formed on a pair of opposite side surfaces of the stacked structure, respectively; a common first gate and a common second gate formed on the other pair of opposite side surfaces of the stacked structure, respectively; a tunnel dielectric layer formed between the first and second gates and the first and second active layers; and a charge trap layer, storing charges that tunnel through the tunnel dielectric layer, interposed between the tunnel dielectric layer and the first and second gates.
The multi bits flash memory device may further include an assistant control electrode, connected to the second active layer, through which a body voltage is applied. In addition, the substrate may be electrically connected to the first active layer, and dopants used to dope the substrate and the first active layer may have the same conductivity type. The first active layer may be formed by patterning the substrate with a mesa-like form.
In addition, a flash memory device according to an embodiment of the present invention includes: two nMOS transistors, having a common source, a common drain, independent gates, and a charge trap layer formed below the independent gate formed on a substrate; two pMOS transistors, having the common source, the common drain, independent gates, and a charge trap layer; and an isolation layer formed between the nMOS transistors and the pMOS transistors such that an n-channel and a p-channel are electrically separated.
The two nMOS transistors use a common p-type first active layer, and the two pMOS transistors use a common n-type second active layer, which is separated from the first active layer by the isolation layer and forms a stacked structure with the first active layer and the isolation layer. The gates may be formed on a pair of opposite side surfaces of the stack of the first active layer and the second active layer, respectively. The source and the drain may be formed on the other pair of opposite side surfaces of the stack.
The 3-dimensional flash memory device according to an embodiment of the present invention may have at least 4 charge storage nodes. By combining various voltage conditions and various electric field conditions, the memory device can store at least 4 bits, for example 4 bits or 8 bits.
Program/erase and read operations can be performed in each of more than 4 charge storage nodes. That is, independent program/write and read operations can be realized. The independent operation allows high-speed program/erase and read operations. In addition, retention characteristics and reliability can be improved.
While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims.
Seo, Sun-Ae, Kim, Won-joo, Park, Yoon-dong, Shin, Sang-min, Lee, Jung-Hoon, Lee, Eun-hong, Chang, Seung-Hyuk
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